JP3631225B2 - Image processing apparatus, image processing apparatus control method, and image processing apparatus control program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image processing apparatus having a plurality of image processing functions.
[0002]
[Prior art]
Conventionally, various information processing apparatuses such as a PC (personal computer), a printer, a scanner, and the like that are connected to a network (a WAN such as the Internet, a LAN, etc.) are known.
[0003]
Currently, IP (Internet Protocol) is a widely used protocol for devices connected to a network. In this method, each device is assigned a unique IP address and is identified based on the IP address.
[0004]
In the conventional IP protocol (IPv4: IP version 4), one address is assigned to one network interface for identification from other terminals on the network.
[0005]
On the other hand, in IPv6 (IP version 6), which has become widespread in recent years, when a terminal is connected to a router, a technology for communicating with the router and automatically acquiring an IP address is defined. Also, one network interface was operated to obtain one IP address.
[0006]
Therefore, even in a multi-function terminal, for example, an image processing apparatus that combines a plurality of functions such as a scanner, a printer, and a facsimile, according to the above-described conventional method, an address for identifying from other terminals on the network is It was one.
[0007]
[Problems to be solved by the invention]
According to the above-described conventional method, in many cases, there is one IP address that can be assigned to a device having only one network interface. For example, a multifunction terminal having a plurality of functions such as a scanner, a printer, and a facsimile is used. Even if it exists, it is recognized as only one terminal from other devices on the network, and all the devices must provide services through this IP address.
[0008]
Therefore, the driver software for operating a multifunction terminal such as a composite image processing apparatus requires not only driver software for operating each function but also a complicated process including a function for mediating the operation of each function. There was a problem that the design of the driver software took a lot of man-hours because of its many functions.
[0009]
Also, for a PC that uses a multi-function terminal such as a composite image processing apparatus, driver software having a large program capacity and complicated operation must be installed, which is a heavy load. For example, even when a PC is used only as a printer, multi-function driver software including scanner and PC-FAX functions must be installed, and driver software heavy on the PC must be installed. Further, even when viewed from the PC user, after starting the driver software of the composite image processing apparatus itself, at least a function (image reading, printing, facsimile transmission, etc.) to be executed by the composite image processing apparatus must be selected. Therefore, there was a problem that the operation becomes complicated.
[0010]
Although it is not impossible to assign an IP address to each function of a scanner, printer, facsimile, etc. of a multifunction terminal even with the conventional system of one network interface and one address, a network such as an Ethernet (trade name) card for each function An interface has to be provided, and there is a problem that the configuration is complicated and expensive.
[0011]
An object of the present invention is to solve the above problems, to improve the operability of a multi-function image processing apparatus with a simple and inexpensive configuration using IPv6 technology, and to easily design necessary system software. It is in.
[0012]
By allocating the IP address to each image processing function, it seems that the image processing apparatus having each function is independently connected to the LAN from the PC. Each can be designed independently, which has the effect of reducing the number of driver design steps. In addition, since the configuration of the driver software can be simplified, it is possible to design driver software with a light load on the PC. Furthermore, if driver software is created for each function, it is sufficient for the user to activate a necessary driver when necessary, and the operability from the PC is improved. In addition, it is possible to install only a driver having a necessary function.
[0013]
[Means for Solving the Problems]
In order to solve the above problems, according to the present invention, an image processing apparatus having a plurality of image processing functions, a control method thereof, and a control program thereof connect to an IPv6 router on the network, and prefix information from the IPv6 router. And generating a unique IP address corresponding to each of the plurality of image processing functions based on the acquired prefix information, and other devices on the network via the IP address generated for each image processing function And adopting a configuration in which each of the plurality of image processing functions is operated according to a communication result.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0015]
FIG. 1 shows a configuration of an image processing apparatus (composite image processing apparatus) 201 that combines a plurality of functions of a scanner, a printer, and a facsimile as a terminal apparatus embodying the present invention.
[0016]
In FIG. 1, a control unit 101 is a system control unit, and controls the entire terminal device composed of each block shown in the figure.
[0017]
The ROM 102 stores a control program of the control unit 101, an operating system (OS) program, and the like. The control unit 101 controls the operation of the terminal device according to the control program stored in the ROM 102.
[0018]
In the present invention, each control program stored in the ROM 102 is subjected to software control such as scheduling and task switching under the management of an OS program (stored in the ROM 102 or other storage medium).
[0019]
The RAM 103 is used for arithmetic processing, storage of setting values registered by the operator, device management data, and the like, and storage of an IP address acquired when the terminal device is connected to the IPv6 router.
[0020]
The buffer memory 104 is for accumulating read image data and received image data, and accumulating data packets transmitted and received via the LAN. As shown in FIG. 3, the buffer memory 104 is divided into a printer area 104a, a scanner area 104b, a PC-FAX area 104c, an image area 104d, and the like. The control task for each function exchanges data packets in the buffer area for each task in the buffer memory 104 divided as described above.
[0021]
The operation unit 105 includes various input keys, an LED, an LCD, and the like, and performs various input operations by an operator, displays the operation status of the image processing apparatus, and the like.
[0022]
The reading processing unit 106 optically reads a document with a photoelectric conversion element in the reading unit 107 and performs various image processing such as binarization processing and halftone processing on the image signal converted into electrical image data, and performs high definition. Output image data.
[0023]
The reading processing unit 106 is controlled by a scan control task program of a control program stored in the ROM 102. The reading unit 107 is configured by a photoelectric conversion element such as a CCD or a contact image sensor.
[0024]
The recording processing unit 108 performs resolution conversion processing and smoothing processing on the recorded image data in order to record image data by the recording unit 109. Also, when a failure such as no paper, paper jam, or toner (or ink) runs out in the recording unit 109, failure information is received from the recording unit 109 and notified to the control unit 101.
[0025]
The recording processing unit 108 is controlled by a printer control task program that is a control program stored in the ROM 102. The recording unit 109 is configured by a laser beam printer, an ink jet printer, or the like, and includes a recording paper detection unit, a toner (or ink) detection unit, and a jam detection unit.
[0026]
The communication processing unit 110 includes a modem (modem / demodulation device), an NCU (network control device), and the like, is connected to a communication line 301 such as a PSTN, and is based on T.T. Communication control using 30 protocol, and line control such as outgoing and incoming calls to the communication line are performed. The communication processing unit 110 is controlled by a communication control task program of a control program stored in the ROM 102.
[0027]
The encoding / decoding processing unit 111 performs encoding / decoding processing for compressing / decompressing image data. The encoding / decoding processing unit 111 mainly depends on encoding / decoding methods such as MH and MR used in facsimile communication, or device specifications. Supports encoding / decoding schemes such as JPEG and MPEG.
[0028]
The LAN control unit 115 performs control for communicating with other devices via the LAN. The LAN control unit 115 includes a NIC (network interface card) such as an Ethernet (trademark) card, and a control circuit thereof (NIC control means may be configured by software of the control unit 101).
[0029]
By using the LAN control unit 115, protocol control can be performed in accordance with a standard such as TCP / IP on a physical network such as Ethernet (trade name). For example, each terminal device can be controlled at a speed of 10Base / T. It is possible to receive a data packet destined for the IP address acquired in the function and transmit a data packet from the terminal device. When receiving the data packet, the LAN control unit 115 notifies the control unit 101.
[0030]
The LAN control unit 115 is connected to the IPv6-compatible router 303 via the LAN cable 302.
[0031]
In FIG. 1, reference numeral 120 denotes a system bus that connects the control unit 101 and each block.
[0032]
The apparatus of FIG. 1 can operate as a printer, a scanner, or a PC-FAX according to a command from a PC (personal computer) connected to the LAN. Details of each operation will be described below.
[0033]
First, the automatic address acquisition operation standardized in IPv6, which is the premise of the present invention, will be described.
[0034]
In IPv6, when a terminal device (201 in FIG. 1) is connected to an IPv6 router (303 in FIG. 1), the terminal device sends a 64-bit numerical value (referred to as a prefix) unique to the router allocated to the router. Request. When this prefix is sent, the terminal device itself generates a 64-bit numerical value called an interface ID and combines it with the prefix sent from the router to complete a total 128-bit IP address. Next, the completed IP address is transmitted on the LAN, and it is checked whether there is a terminal using the same IP address. If there is no duplication, it is determined as the IP address of the terminal device. If there is a duplicate, the interface ID value is changed and the duplicate is confirmed again. If there is no duplicate, the IP address is determined. This is the IPv6 automatic address acquisition operation.
[0035]
Here, the address acquisition sequence as described above in the terminal device of the present invention will be described with reference to the flowchart of FIG. Note that the control procedures in the flowcharts in FIG.
[0036]
When the terminal device (201 in FIG. 1) is connected to the IPv6 router (303 in FIG. 1) in step S101 of FIG. 4, the following control is performed.
[0037]
First, in step S102, the control unit 101 transmits a command requesting a router prefix from the LAN control unit to the router.
[0038]
When a prefix is received from the router in step S103, in step S104, the control unit adds a predetermined 64-bit numerical value as an interface ID to the received prefix to generate an IP address.
[0039]
When the IP address is generated, in step S105, the generated address is transmitted to the network, and it is confirmed whether there is a terminal having the same address under the router.
[0040]
If no duplication is confirmed in step S106, the process proceeds to step S107 to determine the IP address of this terminal. When the first IP address is determined, the control unit recognizes that address as the printer IP address.
[0041]
When the first IP address is determined, the control unit returns to step S102, transmits a prefix request command to the router again through the LAN control unit, and repeats the address acquisition operation in the same manner. When the prefix is sent from the router, in step S104, a numerical value added by 1 to the numerical value added to the previous prefix is added to the prefix, that is, a new address different from the previously acquired address is generated. Send on.
[0042]
As in the previous case, the IP address duplication is confirmed in step S106, and if there is no duplication, it is determined as the second IP address. When the second IP address is determined, the control unit recognizes that address as the scanner IP address.
[0043]
Similarly, when the second address is determined, the process returns to step S102 again, and the control unit transmits a prefix request command to the router again through the LAN control unit, and repeats the address acquisition operation.
[0044]
When the prefix is sent from the router, in step S104, a numerical value obtained by adding 1 to the numerical value added to the previous prefix is added to the prefix to generate a new address. In step S105, the new address is transmitted. As in the previous case, the IP address duplication is confirmed in step S106, and if there is no duplication, it is determined as the third IP address. When the third IP address is determined, the control unit recognizes that address as an IP address for PC-FAX.
[0045]
As described above, in this embodiment, a plurality of IP addresses are acquired by plug and play control with the router. In the present embodiment, since there are three functions of the terminal device of FIG. 1, that is, a printer, a scanner, and a PC-FAX, it is assumed that three IP addresses are acquired. In step S109, it is determined whether or not these three IP addresses have been acquired. If three IP addresses are determined, the IP address acquisition process in FIG. 4 is terminated.
[0046]
In FIG. 4, since the terminal device of FIG. 1 has three functions of a printer, a scanner, and a PC-FAX, three IP addresses are acquired. However, in a terminal device that can operate a plurality of functions from a PC, The above address acquisition operation may be repeated for the number of functions.
[0047]
Also, in FIG. 4, if there is an address overlap in the address acquisition operation, the process proceeds to step S108, the numerical value added to the prefix is incremented by 1, and the address acquisition operation is repeated to obtain a non-overlapping address. look for.
[0048]
Note that the numerical value of the 64-bit interface ID added to the prefix may be generated based on a MAC (Media Access Control) address allocated to the terminal device. In this case, in IPv6, as shown in FIG. 9, a method of inserting a fixed value “fffe” (hexadecimal number) in the middle of the 48-bit MAC address is determined.
[0049]
In FIG. 9 (the address numerical values are expressed in hexadecimal notation), the 48-bit MAC address 901 is divided into two 24-bit blocks 901a and 901b (the seventh bit of the upper block 901a is inverted and "01" to "03". The interface ID 902 is generated by inserting the “fffe” (hexadecimal) block 901c in the middle. A final IP address 903 can be generated from the interface ID 902 and the prefix 900 acquired from the router.
[0050]
With the processing in FIG. 4, a necessary number of IP addresses can be acquired according to the number of functions of the device, and an IP address can be acquired for each function of the terminal device. As described above, by acquiring an IP address for each function, only one terminal device is physically connected to the network. However, other devices such as a PC on the LAN include printers, scanners, and the like. PC-FAX can be seen as if each is connected to the LAN independently.
[0051]
Next, an operation based on a command from the PC (or another device on the LAN) will be described.
[0052]
FIG. 2 is a conceptual diagram showing the control program configuration and data packet flow of the terminal device of the present invention. As shown in the figure, the control program for the terminal device of the present invention executed by the control unit 101 includes control tasks 1011, 1012, 1013 for controlling the respective operations of printing, scanning, and PC-FAX, and a LAN. A transfer task 1014 for controlling the exchange of data packets between them, and a main task 1010 for comprehensively managing these control tasks. Each control task is managed by the OS and processed in a time-sharing manner by optimal task switching. Data packets are exchanged between the LAN connection means 115 and each operation task via the transfer task 1014.
[0053]
Among the above, the transfer task 1014 is a task program for controlling transmission / reception of data packets between the control task for each operation and the PC. When the LAN control unit receives a data packet from the PC, the transfer task 1014 starts. The destination IP address is confirmed, and the data packet is stored in the buffer area (104a, 104b... In FIG. 3) of the control task specified by the IP address.
[0054]
Further, when the task is started by OS task switching, the buffer areas of the control tasks 1011 to 1013 of the respective functions are checked. If there is a transmission packet, the transmission packet is transferred to the LAN control unit 115 via the transfer task 1014. To send. Of course, this packet transmission (and reception) processing is performed according to the IPv6 IP protocol.
[0055]
FIG. 5 shows a specific control procedure of the transfer task 1014.
[0056]
When the transfer task 1014 is activated, it is first checked in step S201 whether a data packet has been received. If a packet has been received, the process proceeds to step S202, where the packet received from the LAN control unit 115 is read to check the destination IP address. .
[0057]
In step S203, the packet is stored in the buffer area of the control task designated by the IP address in the buffer memory 104.
[0058]
In step S204, it is checked whether there is a transmission packet in the print area 104a of the buffer memory. If there is a transmission packet, the packet is transferred to the LAN control unit 115 in step S205 and transmitted on the LAN.
[0059]
In step S206, it is checked whether there is a transmission packet in the scan area 104b of the buffer memory. If there is a transmission packet, in step S207, the packet is transferred to the LAN control unit 115 and transmitted on the LAN. In step S208, it is checked whether there is a transmission packet in the PC-FAX area 104c of the buffer memory. If there is a transmission packet, in step S209, the packet is transferred to the LAN control unit 115 and transmitted on the LAN.
[0060]
Here, the printing operation will be described. The PC (or other terminal on the LAN) converts the image to be recorded into image data suitable for the printer of the terminal device by printer driver software installed on the PC, and the IP address of the printer of the terminal device is A data packet is transmitted together with a command required for printing through the LAN. The LAN control unit 115 receives the transmitted data packet and notifies the control unit 101 of it. The control unit 101 activates the transfer task 1014, confirms the destination address of the data packet received by the LAN control unit 115, and stores it in the print area 104a of the buffer memory because the destination is a printer. The transfer task 1014 sequentially stores the data packet for the printer in the print area 104a of the buffer memory every time it receives a data packet for the printer. When the data packet is received at the printer IP address, the control unit 101 activates the print control task 1101.
[0061]
The print control task 1011 sequentially reads data stored in the print area 104a of the buffer memory, analyzes a print command therefrom, and records sequentially sent image data by the recording unit according to the command.
[0062]
FIG. 6 shows a control procedure of the print control task 1011.
[0063]
When the print task is activated, it is first checked in step S301 whether a data packet has been received in the print area 104a of the buffer memory. If a packet has been received, the process proceeds to step S302 and a command for recording whether the received packet is image data. Check if it is data. If it is command data, the command is analyzed in step S303 to prepare a recording environment required by the PC. If the packet is image data in step S302, the process proceeds to step S304 to perform data processing in accordance with the recording unit 109 in accordance with the command data. In step S305, the image data is transferred to the recording unit 109 to record an image. . The end of the recording process is determined by detecting the end command or the end of the recording data in step S306.
[0064]
Next, in the scan operation, the scanner driver software installed on the PC uses the IP address of the scanner of the terminal device through the LAN with a command for specifying the reading operation such as the reading resolution, the reading mode, the reading size, and the reading start command as packets. Send to. Similar to the printer operation, the LAN control unit 115 receives the transmitted data packet and notifies the control unit 101 of the received data packet. The control unit 101 activates the transfer task 1014, confirms the destination address of the data packet received by the LAN control unit 115, and stores it in the scanner area 104b of the buffer memory because the destination is a scanner. The transfer task 1014 sequentially stores the data packet for the scanner in the scanner area 104b of the buffer memory each time it receives the data packet for the scanner. When the data packet is received at the scanner IP address, the control unit 101 activates the scan control task 1012.
[0065]
The scan control task 1012 analyzes the command data stored in the scan area 104b of the buffer memory, reads the document placed on the document table of the terminal device by the reading method specified by the command, and the reading processing unit The destination of the PC is added to the read data subjected to the image processing to form a packet, which is sequentially stored in the scanner area 104b of the buffer memory. If a transmission packet of scan data is written in the scanner area 104b of the buffer memory when the transfer task 1014 is activated, the transfer task 1014 transmits the data from the LAN control unit 115 to the PC.
[0066]
FIG. 7 shows a control procedure of the scan task 1012. When the scan task 1012 is activated, it is checked in step S401 whether a data packet is received in the scan area 104b of the buffer memory. If a packet is received, the process proceeds to step S402 to analyze the received packet command.
[0067]
In step S403, the scanning operation by the reading unit 107 is started in accordance with the instruction of the scan command analyzed in step S402. When an image for one line is read in step S404, image processing is performed by the image processing unit 106 in step S405, which is converted into digital data. In step S406, a packet having the designated IP address as a destination is converted into a packet. Store in the scan area 104b. The operations from step S404 to S406 are repeated for the number of lines specified by the command. The packet stored in the scan area 104b of the buffer memory is transmitted on the LAN by the transfer task 1014 described above. The end of scanning is determined by detecting conditions such as the end of paper in step S407.
[0068]
When sending image data by fax with PC-FAX operation, specify the fax communication operation such as the telephone number of the other party, image resolution, image size, communication speed, etc. using the PC-FAX driver software installed on the PC. The command and transmission image data are packetized and transmitted to the PC-FAX IP address of the terminal device through the LAN. The LAN control unit 115 receives the transmitted data packet and notifies the control unit 101 of it. The control unit 101 activates the transfer task 1014, confirms the destination address of the data packet received by the LAN control unit 115, and stores it in the PC-FAX area 104c of the buffer memory because the destination is PC-FAX. The transfer task 1014 sequentially stores the data packet for PC-FAX in the area 104c in the PC-FAX of the buffer memory every time it receives the data packet. When the data packet is received at the PC-FAX IP address, the control unit 101 activates the PC-FAX control task 1013.
[0069]
The PC-FAX control task analyzes command data stored in the PC-FAX area of the buffer memory, controls the NCU of the communication control unit 110, and makes a call to the FAX transmission destination telephone number designated by the command. CCITT T. The communication protocol in accordance with the Recommendation 30 is executed, the image data sent from the PC is encoded (by the encoding / decoding processing unit 111) by the encoding method supported by the transmission destination FAX, and the communication processing unit 110 Transmit with modulation by modem. At this time, if the transmission destination FAX does not support the resolution and communication speed designated by the PC, a fallback process is performed as appropriate.
[0070]
FIG. 8 shows a control procedure of the PC-FAX task 1013. When the PC-FAX task 1013 is activated, it is checked in step S501 whether a data packet has been received in the PC-FAX area 104c of the buffer memory. If a packet has been received, the process proceeds to step S502 to determine whether the received packet is image data. Check if it is command data for transmission.
[0071]
If command data for FAX transmission is detected, the command is analyzed in step S503, and the transmission conditions, destination telephone number, etc. are confirmed. If the packet is image data in step S502, the process advances to step S504 to store the image data in the image area 104d of the buffer memory.
[0072]
When all the image data to be transmitted is received in step S505, a call is made to the telephone number designated from the PC in step S506. When the other party's FAX responds, the CCITT T.P. The facsimile pre-procedure according to the 30 recommendation is performed, the image data stored in the buffer memory is encoded by the encoding / decoding processing unit 111 in accordance with the FAX of the transmission destination in step S508, and the communication processing unit 110 in step S509. And send it to the telephone line with modulation.
[0073]
If it is confirmed in step S510 that all the image data has been transmitted, a post-facsimile procedure is performed in step S511, and communication is terminated. The operations from the call origination in step S506 to the post-facsimile procedure in step S511 are the same as those in CCITT T.264. This is a FAX transmission procedure according to the 30 recommendation. T. T. et al. Since the facsimile procedure according to the 30 recommendation is publicly known, further detailed description of the facsimile procedure is omitted in this embodiment.
[0074]
As described above, the control tasks 1011 to 1013 for controlling printing, scanning, and FAX transmission / reception are managed by the OS and are time-division processed by optimal task switching. Packet data exchange with the PC is also physically performed between the control task areas (FIG. 3) of the buffer memory in the terminal device, and even if a plurality of operations are requested from the PC at the same time. Can be processed at the same time. That is, the control tasks 1011 to 1013 for controlling printing, scanning, and FAX transmission / reception by time division processing are executed as if separate single-function devices are operating.
[0075]
For example, a case where a print operation and a scan operation are requested at the same time will be described. First, when print data is sent from a PC, the transfer task 1014 is activated and print data received from the LAN control unit is printed in the print area of the buffer memory. The data are sequentially stored in 104a. Subsequently, when the print task 1011 is activated by OS task switching, the print task 1011 reads and records the print data stored in the buffer memory. Next, when the task is switched and the scan task 1012 is activated, the scan task 1012 accumulates the generated scan data in the scan area 104b of the buffer memory. Next, when the transfer task 1014 is activated, if scan data is prepared in the scan area 104b of the buffer memory, the transfer task 1014 transfers the scan data to the LAN control unit 115 and transmits it to the PC.
[0076]
In this way, the print data sent from the PC is stored in the buffer memory, and the print data stored in the buffer memory is recorded only while the print task 1011 is activated. Therefore, the print data can be received even if the print task 1011 is not activated. Also in the scan, the generation of scan data and the transfer to the PC are performed by separate tasks, and when the transfer task 1014 is activated, if the scan data is in the scan area 104b of the buffer memory, it is transmitted to the PC. Therefore, the scan task only needs to generate scan data for the time allocated by the OS, and simultaneous printing and scanning are possible.
[0077]
In the above description, the combination of print and scan processing has been described. However, the above time-division multiplex processing is also possible in any combination of the functions constituting the terminal in FIG. 1, and a plurality of operations are requested at the same time. Can also work at the same time.
[0078]
As described above, only one control unit and one LAN connection means are used, and a plurality of unique IP addresses are acquired for each of a plurality of functions (print, scan, facsimile communication in the above example). Through the address, the terminal device can be operated as if it were separate devices that are independent on the LAN and capable of simultaneous operation.
[0079]
That is, according to the present embodiment, a plurality of unique IP addresses are obtained for each function of the image processing apparatus having a complex function with a simple and inexpensive configuration using only a single LAN connection means, and these IP addresses are obtained. Therefore, each function of the image processing apparatus can be operated independently, so that the operability of the image processing apparatus can be improved.
[0080]
Each function of the image processing apparatus performs input / output using a corresponding IP address and operates by a task program driven in a time-sharing manner by task switching. Also, data input / output is a buffer for each task. Since it can be performed using the memory area, the system software for executing each function of the image processing apparatus can be designed and developed more easily as a highly independent task program module. In some cases, a task program module for executing each function of the image processing device by simply reworking the software of a single-function device (printer for a printer, scanner for a scanner ...) that is operated on a network. Can be diverted to
[0081]
Further, when viewed from a PC using the image processing apparatus, each function of the image processing apparatus appears as a separate device having an independent IP address on the network. From the PC side, a driver program corresponding to a function required by the user is installed, such as a printer driver program for a printer and a scanner driver program for a scanner, and each function of the image processing apparatus is accessed via the driver program. Therefore, the user does not need to install a complicated and large-capacity driver program in the PC as in the conventional composite image processing apparatus, and the resources such as the memory and the disk of the PC can be greatly saved.
[0082]
In the above, for convenience, the network connected via the router (303 in FIG. 1) has been described as “LAN”. However, even if the network described in the router is a WAN such as the Internet, Needless to say, all the explanations are valid.
[0083]
In addition, the communication protocol (TCP / IP, UDP / IP, or higher-level socket service, etc.) in a layer higher than the IP protocol has not been described in detail, but an arbitrary resource sharing service (for example, a printer / file) It goes without saying that shared services) and their protocols can be used.
[0084]
The control procedures shown in the flowcharts of FIGS. 4 to 8 are usually stored in the ROM 102 and executed as they are or expanded on the RAM 103, but a program for realizing the present invention should be stored. The storage medium is not limited to the ROM 102 described above, and may be an arbitrary storage medium such as a flexible disk, an MO, and a CD-ROM. Further, the program supply path for realizing the present invention is not limited to these storage media, and may be configured to be downloaded / installed via a network, for example.
[0085]
1 has been described as an image processing apparatus that combines the three functions of printing, scanning, and facsimile communication. However, in the image processing apparatus, the types and number of functions to which independent IP addresses should be assigned. Needless to say, is not limited to the above three.
[0086]
【The invention's effect】
As is apparent from the above description, according to the present invention, an image processing apparatus having a plurality of image processing functions, a control method thereof, and a control program thereof are connected to an IPv6 router on the network and prefixed from the IPv6 router. Information is acquired, a unique IP address is generated corresponding to each of the plurality of image processing functions based on the acquired prefix information, and other IP on the network is generated via the IP address generated for each image processing function. Since it employs a configuration that communicates with a device and operates each of the plurality of image processing functions in accordance with the communication result, the operability of the image processing apparatus with multiple functions can be improved by using IPv6 technology and a simple and inexpensive configuration. It is possible to improve and to easily design necessary system software.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a composite image processing apparatus as a terminal apparatus adopting the present invention.
FIG. 2 is an explanatory diagram showing a configuration of a control task of the apparatus of FIG. 1;
FIG. 3 is an explanatory diagram showing a configuration of a buffer memory of the apparatus of FIG. 1;
FIG. 4 is a flowchart showing IP address acquisition processing in the apparatus of FIG. 1;
FIG. 5 is a flowchart showing a transfer task in the apparatus of FIG. 1;
6 is a flowchart showing a print task in the apparatus of FIG. 1. FIG.
FIG. 7 is a flowchart showing a scan task in the apparatus of FIG. 1;
FIG. 8 is a flowchart showing a facsimile communication task in the apparatus of FIG.
FIG. 9 is an explanatory diagram showing a method for generating an interface ID in IPv6.
[Explanation of symbols]
101 Control unit
102 ROM
103 RAM
104 Buffer memory
105 Operation unit
106 Reading processing unit
107 Reading unit
108 Recording processing unit
109 Recording section
110 Communication processing unit
111 Coding / decoding processing unit
115 LAN controller
301 Communication line
302 LAN cable
901 MAC address
902 Interface ID
903 IP address
1010 Main task
1011, 1012, 1013 Control task
1014 Transfer task

Claims (6)

In an image processing apparatus having a plurality of image processing functions,
IP address generation means for connecting to an IPv6 router on the network, acquiring prefix information from the IPv6 router, and generating a unique IP address corresponding to each of the plurality of image processing functions based on the acquired prefix information;
An image having control means for communicating with other devices on the network via an IP address generated for each image processing function and operating each of the plurality of image processing functions according to a communication result Processing equipment. The control means executes the plurality of image processing functions by time-sharing the control task program corresponding to each of the plurality of image processing functions by task switching, and generates an IP address for each of the image processing functions. 2. The image processing apparatus according to claim 1, wherein communication via a control task program corresponding to each of the plurality of image processing functions is executed as a unit. In a control method of an image processing apparatus having a plurality of image processing functions,
An IP address generation process for connecting to an IPv6 router on the network, acquiring prefix information from the IPv6 router, and generating a unique IP address corresponding to each of the plurality of image processing functions based on the acquired prefix information;
An image comprising a control process of communicating with another device on the network via an IP address generated for each image processing function and operating each of the plurality of image processing functions according to a communication result A method for controlling a processing apparatus. According to the control process, the control task program corresponding to each of the plurality of image processing functions is executed in a time-sharing manner by switching tasks, and the plurality of image processing functions are executed, and an IP address generated for each of the image processing functions The method of controlling an image processing apparatus according to claim 3, wherein communication via a control task program corresponding to each of the plurality of image processing functions is executed as a unit. In a control program for an image processing apparatus having a plurality of image processing functions,
An IP address generation process for connecting to an IPv6 router on the network, acquiring prefix information from the IPv6 router, and generating a unique IP address corresponding to each of the plurality of image processing functions based on the acquired prefix information;
An image comprising a control process of communicating with another device on the network via an IP address generated for each image processing function and operating each of the plurality of image processing functions according to a communication result Processing unit control program. According to the control process, the control task program corresponding to each of the plurality of image processing functions is executed in a time-sharing manner by switching tasks, and the plurality of image processing functions are executed, and an IP address generated for each of the image processing functions 6. The control program for an image processing apparatus according to claim 5, wherein communication via the control task program corresponding to each of the plurality of image processing functions is executed as a unit.

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